rfid idic 100 to 150 khz nfiden ti
TRANSCRIPT
TIALRead/Write LF
RFID IDIC100 to 150 kHz
ATA5577
Preliminary
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ATMEL CONFID
EN
Features• Contactless Power Supply• Contactless Read/Write Data Transmission• Radio Frequency fRF from 100 kHz to 150 kHz• Basic Mode or Extended Mode• Compatible with T5557, ATA5567• Replacement for e5551/T5551 in Most Common Operation Modes• Configurable for ISO/IEC 11784/785 Compatibility• Total 363 Bits EEPROM Memory: 11 Blocks (32 Bits + 1 Lock Bit)
– 7 × 32 Bits EEPROM User Memory Including 32-bit Password Memory– 2 × 32 Bits for Unique ID– 1 × 32-bit Option Register in EEPROM to Set Up the Analog Front End:
• Clock and Gap Detection Level• Improved Downlink Timing• Clamp and Modulation Voltage• Soft Modulation Switching• Write Damping like the T5557/ATA5567 or with Resistor• Downlink Protocol
– 1 × 32-bit Configuration Register in EEPROM to Setup:• Data Rate:
– RF/2 to RF/128, Binary Selectable or– Fixed Basic Mode Rates
• Modulation/Coding:– Bi-phase, Manchester, FSK, PSK, NRZ
• Other Options:– Password Mode– Max Block Feature– Direct Access Mode– Sequence Terminator(s)– Blockwise Write Protection (Lock Bit)– Answer-On-Request (AOR) Mode– Inverse Data Output– Disable Test Mode Access – Fast Downlink (~6 Kbits/s versus ~3 Kbits/s)– OTP Functionality– Init Delay (~67 ms)
• High Q-antenna Tolerance Due to Build in Options• Adaptable to Different Applications: Access Control, Animal ID and Waste
Management• On-chip Trimmed Antenna Capacitor:
– 250 pF/330 pF (±3%) – 75 pF/130 pF (On Request)– Without On-chip Capacitor (On Request)
• Pad Options– ATA5577M1
• 100 µm × 100 µm for Wire Bonding or Flip Chip– ATA5577M2
• 200 µm × 400 µm for Direct Coil Bonding
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1. DescriptionThe ATA5577 is a contactless read/write identification IC (IDIC®) for applications in the 125-kHzor 134-kHz frequency band. A single coil connected to the chip serves as the IC’s power supplyand bi-directional communication interface. The antenna and chip together form a transponderor tag.
The on-chip 363-bit EEPROM (11 blocks with 33 bits each) can be read and written block-wisefrom a base station (reader).
Data is transmitted from the IDIC (uplink) using load modulation. This is achieved by dampingthe RF field with a resistive load between the two terminals Coil 1 and Coil 2. The IC receivesand decodes serial base station commands (downlink), which are encoded as 100% amplitudemodulated (OOK) pulse-interval-encoded bit streams.
2. CompatibilityThe ATA5577 is designed to be compatible with the T5557/ATA5567. The structure of the con-figuration register is identical. The two modes, Basic mode and Extended mode, are alsoavailable. The ATA5577 is able to replace the e5551/T5551 in most common operation modes.In all applications, the correct functionality of the replacements must be evaluated and proved.
For further details, refer to Atmel®’s web site for product-relevant application notes.
3. System Block Diagram
Figure 3-1. RFID System Using ATA5577 Tag
Data
Readeror
Base station
ATA5577
Power
1) Mask option
1)
TransponderC
oil i
nter
face
Con
trol
ler
Memory
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4. ATA5577 - Functional Blocks
Figure 4-1. Block Diagram
4.1 Analog Front End (AFE)The AFE includes all circuits that are directly connected to the coil terminals. It generates theIC's power supply and handles the bi-directional data communication with the reader. It consistsof the following blocks:
• Rectifier to generate a DC supply voltage from the AC coil voltage
• Clock extractor
• Switchable load between Coil 1 and Coil 2 for data transmission from the tag to the reader
• Field-gap detector for data transmission from the base station to the tag
• ESD-protection circuitry
4.2 AFE Option RegisterThe option register maintains a readable shadow copy of the data held in the EEPROM block 3page 1. This contains the analog front end’s level and threshold settings, as well as enhanceddownlink protocol selection with which the device can be fine tuned for perfect operation and allapplication environments. It is continually refreshed during read-mode operation and (re-)loadedafter every POR event or reset command. By default the option register is pre-programmedaccording to Table 10-1 on page 40.
4.3 Data-rate GeneratorThe data rate is binary programmable to operate at any even-numbered data rate between RF/2and RF/128 or to any of the fixed Basic mode data rates (RF/8, RF/16, RF/32, RF/40, RF/50,RF/64, RF/100 and RF/128).
Memory
(363-bit EEPROM)
Modulator
AFE option register
Ana
log
fron
t end
Dat
a-ra
tege
nera
tor
Wri
tede
code
r
POR
Coil 2
Coil 1
Controller
Test logic HV generator
Input register
Mode register
1) Mask option
1)
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4.4 Write DecoderThe write decoder detects the write gaps and verifies the validity of the data stream according tothe Atmel e555x downlink protocol (pulse interval encoding).
4.5 HV GeneratorThis on-chip charge pump circuit generates the high voltage required to program the EEPROM.
4.6 DC SupplyPower is externally supplied to the IDIC via the two coil connections. The IC rectifies and regu-lates this RF source and uses it to generate its supply voltage.
4.7 Power-On Reset (POR)The power-on reset circuit blocks the voltage supply to the IDIC until an acceptable voltagethreshold has been reached.
4.8 Clock ExtractionThe clock extraction circuit uses the external RF signal as its internal clock source.
4.9 ControllerThe control logic module executes the following functions:
• Load mode register with configuration data from EEPROM block 0 after power-on and during reading
• Load option register with the settings for the analog front end stored in EEPROM page 1 block 3 after power-on and during reading
• Control all EEPROM memory read/write access and data protection
• Handles the downlink command decoding detecting protocol violations and error conditions
4.10 Mode RegisterThe mode register maintains a readable shadow copy of the configuration data held in block 0 ofthe EEPROM. It is continually refreshed during read mode and (re-)loaded after every PORevent or reset command. On delivery, the mode register is pre-programmed according to Table10-1 on page 40.
4.11 ModulatorThe modulator encodes the serialized EEPROM data for transmission to a tag reader or basestation. Several types of modulation are available including Manchester, bi-phase, FSK, PSK,and NRZ.
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4.12 Memory
The memory is a 363-bit EEPROM, which is arranged in 11 blocks of 33 bits each. Each blockincludes a single Lock bit, which is responsible for write-protecting the associated block. Pro-gramming takes place on a block basis, so a complete block (including lock bit) can beprogrammed with a single command. The memory is subdivided into two page areas. Page 0contains 8 blocks and page 1 contains 3 blocks. All 33 bits of a block, including the lock bit, areprogrammed simultaneously.
Block 0 of page 0 contains the mode/configuration data, which is not transmitted during regularread operations. Addressing block 0 will always affect block 0 of page 0 regardless of the pageselector. Block 7 of page 0 may be used as a protection password.
Block 3 of page 1 contains the analog front end option register, which is also not transmitted dur-ing regular-read operation.
Bit 0 of every block is the lock bit for that block. Once locked, the block (including the lock bititself) is not re-programmable via the RF field.
Blocks 1 and 2 of page 1 contain traceability data and are transmitted with the modulationparameters defined in the configuration register after the opcode “11” is issued by the reader(see Figure 5-10 and Figure 5-11 on page 21). The traceability data blocks are programmed andlocked by Atmel.
Figure 4-2. Memory Map
0 1.........................................................................................32
Pag
e 1
L Analog front end option set-up Block 3
1 Traceability data Block 2
1 Traceability data Block 1
L Page 0 configuration data Block 0
Pag
e 0
L User data or password Block 7
L User data Block 6
L User data Block 5
L User data Block 4
L User data Block 3
L User data Block 2
L User data Block 1
L Configuration data Block 0
32 bits
Not transmitted
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4.13 Traceability Data Structure/Unique IDBlocks 1 and 2 of page 1 contain the traceability data and are programmed and locked by Atmelduring production testing(1). The most significant byte of block 1 is fixed to E0h, the allocationclass (ACL) as defined in ISO/IEC 15963-1. The second byte is therefore defined in ISO/IEC7816-6 as Atmel’s manufacturer ID (15h). The following 8 bits could be used as user ID (UID Bit47 to 40). If not otherwise requested, the 5 most significant bits (customer identification CID) areby default reset (set to 00) as the Atmel standard value (other values may be assigned onrequest for high-volume customers) and the 3 least significant bits (IC revision, ICR) are used byAtmel for the IC and/or foundry version of the ATA5577.
The lower 40 bits of the data encode Atmel’s traceability information and conform to a uniquenumbering system (unique ID). These 40 data bits are divided in two sub-groups, a 5-digitBCD-coded lot-ID number (LotID, 20 bits) and the binary wafer number (wafer#, 5 bits) concate-nated with the sequential die number on wafer (DW,15 bits).
Note: 1. This is only valid for sawn wafer on foil delivery.
Figure 4-3. ATA5577 Traceability Data Structure
ACL Allocation class as defined in ISO/IEC 15963-1 = E0hMFC Atmel Corporation’s manufacturer code as defined in ISO/IEC 7816-6 = 15hUID User ID, on request (otherwise 5-bit CID and 3-bit ICR)LotID 5-digit BCD encoded lot number, e.g., '41577'Wafer# 5 bits for wafer numberDW 15 bits designating sequential die number on wafer
E0
577
Example: 41
8
0015
12 20
12 13 17 18 311 .........
8 9 16 17 24 25 32
3263 MSB
31 0LSB
32
1
DWLotID Wafer #
MFC ICRCID LotIDBlock 1
Bit No.
Bit No.
Bit value
Block 2
ACL
... ...
...
...
......
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5. Operating the ATA5577
5.1 Configuring the ATA5577
Table 5-1. Block 3 Page 1– Analog Front End Option Set-up
L 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32
0 0 0 0 0 0 0 0 0 0
Lo
ck B
it Option Key(1)
So
ft M
od
ula
tio
n
Cla
mp
Vo
ltag
e
Mo
du
lati
on
Vo
ltag
e
Clo
ck-d
etec
tio
n T
hre
sho
ld
Gap
-det
ecti
on
Th
resh
old
Wri
te D
amp
ing
Dem
od
Del
ay
Dow
nlin
k P
roto
col
Reserved for Future Use
(RFU)0 Unlocked
1 Locked
Off 0 0 0 0 0 Fixed Bit Length
One pulse weak 0 1 0 0 1 Long Leading Reference
One pulse strong 1 0 0 1 0 Leading Zero Reference
Two pulses 1 1 0 1 1 1 of 4 Coding Reference
Smooth 1 1 1 0 0 None
Clamp med typ(2). 6 Vp 0 0 0 1 One pulse
RFU 0 1 1 0 Two pulses
Clamp low typ(2). 5 Vp 1 0 1 1 RFU
Clamp high typ(2). 8 Vp 1 1 0 0 0 WD + low att.
Mod med typ(2). 2 Vp 0 0 0 0 1 WD + high att.
RFU 0 1 0 1 0 Low att.
Mod low typ(2). 1 Vp 1 0 0 1 1 High att.
Mod high typ(2). 3 Vp 1 1 1 0 0 WD only
Clkdet med typ. 550 mVp 0 0 1 0 1 Off
RFU 0 1 1 1 0 RFU
Clkdet low typ. 250 mVp 1 0 1 1 1 RFU
Clkdet high typ. 800 mVp 1 1
Gapdet med typ. 550 mVp 0 0
RFU 0 1
Gapdet low typ. 250 mVp 1 0
Gapdet high typ. 850 mVp 1 1
Notes: 1. If Option Key is 6 or 9, the front end options are activated; for all other values they take on the default state (all 0). If Option Key is 6 then the complete page 1 (i.e., option register and traceability data) cannot be overwritten by any Test Write Com-mand. This means, if the Lock bits of the three blocks of page 1 are set and the Option Key is 6, then all of page 1’s blocks are locked against change.
2. Weak field condition
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Table 5-2. Block 0 Page 0 – Configuration Mapping in Basic Mode
L 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32
0 0 0 0 0 0 0 0 0 0 0
Lo
ck B
it
Master Key
(1), (2)Data Bit
Rate
Modulation
PS
KC
F
AO
R
MAXBLOCK P
WD
ST
Seq
uen
ce T
erm
inat
or
Init
Del
ay
RF/8 0 0 0 0 0 RF/2
RF/16 0 0 1 0 1 RF/4
0 Unlocked RF/32 0 1 0 1 0 RF/8
1 Locked RF/40 0 1 1 1 1 Res.
RF/50 1 0 0 0 0 0 0 0 Direct
RF/64 1 0 1 0 0 0 0 1 PSK1
RF/100 1 1 0 0 0 0 1 0 PSK2
RF/128 1 1 1 0 0 0 1 1 PSK3
0 0 1 0 0 FSK1
0 0 1 0 1 FSK2
0 0 1 1 0 FSK1a
0 0 1 1 1 FSK2a
0 1 0 0 0 Manchester
1 0 0 0 0 Bi-phase
1 1 0 0 0 Reserved
Notes: 1. If Master Key is 6 the test mode access is disabled2. If Master Key is neither 6 nor 9, the extended function mode and Init Delay are disabled
Table 5-3. Block 0 Page 0 – Configuration Map in Extended Mode (X-mode)
L 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32
0 0 0 0 1
Lo
ck B
it
Master Key(1), (2) n5 n4 n3 n2 n1 n0
Data Bit Rate
RF/(2n+2) X-m
od
e
Modulation
PSK-CF A
OR
OT
P MAX-BLOCK P
WD
Seq
. Sta
rt M
arke
r
Fast
Dow
nlin
k
Inve
rse
Dat
a
Init
Del
ay
0 0 RF/2
Direct 0 0 0 0 0 0 1 RF/4
0 Unlocked
Locked
PSK1 0 0 0 0 1 1 0 RF/8
1 PSK2 0 0 0 1 0 1 1 Res.
PSK3 0 0 0 1 1
FSK1 0 0 1 0 0
FSK2 0 0 1 0 1
Manchester 0 1 0 0 0
Bi-phase 1 0 0 0 0
Differentialbi-phase
1 1 0 0 0
Note: 1. If Master Key is 6 and bit 15 is set, the test mode access is disabled and the extended mode is active 2. If Master Key is 9 and bit 15 is set, the extended mode is enabled
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5.2 Soft Modulation SwitchingAbrupt rise of the modulation signal at the beginning of modulation - especially in applicationswith high quality antennas - could lead to clock losses and therefore timing violations. To preventthis, several soft modulation settings can be chosen for a soft transition into the modulationstate.
Soft modulation should only be used in combination with modulation schemes and data rateswhich do not involve high frequency modulation changes.
5.3 Demodulation DelaySoft modulation will cause imbalance in modulated and unmodulated phases. Depending on thesoft-modulation setting, the unmodulated phase can be longer than the modulated. To balanceout this mismatch, the switch-point from the modulated to the unmodulated phase can bedelayed for one or two pulses.
These delays and soft modulation switching should only be used in combination with modulationschemes and data rates which do not involve high frequency-modulation changes.
Table 5-4. Soft Modulation Switching Scheme
Bit 5-7 (bl3 p1) 000 010 100 110 111
Description No soft modulation One pulse weak One pulse strong Two pulses Smooth
dampclamp 75% 50%
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5.4 Write DampingReader to Tag communication is initialized by sending a start-gap from the reader station. Toease gap detection respective to detect subsequent field-gaps reliably by default the receivedamping and the low attenuation is activated.
Especially in combination with high quality coils a higher attenuation factor can be switched on,to fasten the relaxation time.
Using antenna-coils with low Q-factor it might be feasible to switch off the write damping. Thisresults to better energy balance and therefore improved write distance.
5.5 Initialization and Init-DelayThe Power-On-Reset (POR) circuit remains active until an adequate voltage threshold has beenreached. This, in turn, triggers the default initialization delay sequence. During this configurationperiod of about 192 field clocks, the ATA5577 is initialized with the configuration data stored inEEPROM block 0 and with the options stored in block 3 page 1. There are two variants of theATA5577 implemented (see Section 10. “Ordering Information” on page 39). The variant of theATA5577 with damping during initialization shows permanent damping during initialization (seeFigure 5-9 on page 20). This prevents the tag from generating a power on reset at the edge ofoperating distance. This improves the stability of operation in all applications where maximumread range is not required. The ATA5577 types without damping achieve a longer read rangebased on the lower activation field strength.
Table 5-5. Demodulation Delay Scheme
Bits 19 and 20 (bl3 p1) Description
00
01
10
C1-C2
mod
C1-C2
mod
No demodulation delay
Demodulation delayone pulse
Demodulation delaytwo pulses
C1-C2
mod
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Tag modulation in regular-read mode will be observed about 3 ms after entering the RF field. Ifthe Init-delay bit is set, the ATA5577 variant with damping during initialization remains in a per-manent damping state for t ~ 69 ms at f = 125 kHz. The ATA5577 variant without damping willstart modulation after t ~ 69 ms without damping.
• Init-delay = 0: TINIT = 192 × TC + TPOR ~ 3 ms; TC = 8 µs at f = 125 kHz(TPOR denotes delay for POR and depends on environmental conditions)
• Init-delay = 1: TINIT = (192 + 8192) × TC + TPOR ~ 69 ms;
Any field gap occurring during this initialization phase will restart the complete sequence. Afterthis initialization time, the ATA5577 enters regular-read mode and modulation starts automati-cally using the parameters defined in the configuration register.
5.6 Modulator in Basic ModeThe modulator consists of data encoders for the following types of modulation in Basic mode:
5.7 MaxblockAfter entering regular-read mode the ATA5577 transmits the data content starting with block 1.The MAXBLK setting defines how many data blocks will be transmitted.
5.8 PasswordWhen password mode is active (PWD = 1), the first 32 bits after the opcode are regarded as thepassword. They are compared bit by bit with the contents of block 7, starting at bit 1. If the com-parison fails, the ATA5577 will not program the memory, instead it will restart in regular-readmode once the command transmission is finished.
Note: In password mode, MAXBLK should be set to a value lower than 7 to prevent the password from being transmitted by the ATA5577.
Each transmission of the direct access command (two opcode bits, 32-bit password, '0' bit plus 3address bits = 38 bits) needs about 18 ms. Testing all possible combinations (about 4.3 billion)would take about two years.
Table 5-6. Types of Modulation in Basic Mode
Mode Direct Data Output
FSK1a(1) FSK/8 - FSK/5 0 = RF/8 1 = RF/5
FSK2a(1) FSK/8 - FSK/10 0 = RF/8 1 = RF/10
FSK1(1) FSK/5 - FSK/8 0 = RF/5 1 = RF/8
FSK2(1) FSK/10 - FSK/ 8 0 = RF/10 1 = RF/8
PSK1(2) Phase change when input changes
PSK2(2) Phase change on bit clock if input high
PSK3(2) Phase change on rising edge of input
Manchester 0 = falling edge, 1 = rising edge
Bi-phase 1 creates an additional mid-bit change
NRZ 1 = damping on, 0 = damping off
Notes: 1. A common multiple of bit rate and FSK frequencies is recommended.
2. In PSK mode the selected data rate has to be an integer multiple of the PSK sub carrier frequency.
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5.9 Answer-On-Request (AOR) ModeWhen the AOR bit in the configuration register is set the ATA5577 does not start modulation inthe regular-read mode after loading configuration block 0. The tag waits for a valid AOR datastream (wake-up command) from the reader before modulation is enabled. The wake-up com-mand consists of the opcode (“10” or “11”) followed by a valid password. The selected tag willremain active until the RF field is turned off or a new command with a different password istransmitted, which may address another tag in the RF field.
Figure 5-1. Answer-On-Request (AOR) Mode, For Example, Fixed Bit-length Protocol
Table 5-7. ATA5577 - Modes of Operation
PWD AOR Behavior of Tag after Reset Command or POR De-activate Function
1 1
Answer-On-Request (AOR) mode:
- Modulation starts after wake-up with a matching password
- Programming needs valid password
Command with non-matching password deactivates the selected tag
1 0Password mode: - Modulation in regular-read mode starts after reset
- Programming and direct access needs valid password
0 -
Normal mode:
- Modulation in regular-read mode starts after reset - Programming and direct access without password
Loadingconfigurationand option
No modulationbecause AOR = 1
POR
VCoil1 - Coil2
Damping during initialization Modulation
AOR wake-up command(with valid PWD)
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Figure 5-2. Anticollision Procedure Using AOR Mode
"Select a single tag"send OPCODE + PWD "wake up command"
Initialize tags withAOR = 1, PWD = 1
POWER ON RESETRead configuration
Password correct ?
TagReader
Decode data
No
No
Yes
Yes
Send block 1 to MAXBLK
Receive damping ON
Enter AOR mode
Field ON OFF
Field OFF ON
Wait for OPCODE +PWD "wake up
command"
Wait for tW > 2.5 ms
All tags read?
Exit
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5.10 ATA5577 in Extended Mode (X-mode)In general, setting of the master key (bits 1 to 4) of block 0 to the value 6 or 9 together with theX-mode bit will enable the extended mode functions such as the binary bit-rate generator, OTPfunctionality, fast downlink, inverse data output and sequence start marker.
• Master key = 9: Test mode access and extended mode are both enabled.
• Master key = 6: Any test mode access will be denied but the extended mode is still enabled.
Any other master key setting will prevent the activation of the ATA5577 extended mode options,even when the X-mode bit is set.
5.10.1 Modulator in Extended-Mode
5.10.2 Binary Bit-rate GeneratorIn extended mode the data rate is binary programmable to operate at any even-numbered datarate between RF/2 and RF/128 as given in the formula below.
Data rate = RF / (2n + 2)
5.10.3 OTP FunctionalityIf the OTP bit is set to 1, all memory blocks are write protected and behave as if all lock bits areset to 1. If, in addition, the master key is set to 6, the ATA5577 mode of operation is locked for-ever (one-time-programming functionality).
If the master key is set to 9, the test-mode access allows the re-configuration of the tag.
Table 5-8. ATA5577 Types of Modulation in Extended Mode
Mode Direct Data Output Encoding Inverse Data Output Encoding
FSK1(1) FSK/5 - FSK/8 0 = RF/5; 1 = RF/8 FSK/8 - FSK/5 0 = RF/8; 1 = RF/5 (= FSK1a)
FSK2(1) FSK/10 - FSK/8 0 = RF/10; 1 = RF/8 FSK/8 - FSK/10 0 = RF/8; 1 = RF/10 (= FSK2a)
PSK1(2) Phase change when input changes Phase change when input changes
PSK2(2) Phase change on bit clock if input high Phase change on bit clock if input low
PSK3(2) Phase change on rising edge of input Phase change on falling edge of input
Manchester 0 = falling edge, 1 = rising edge mid bit 1 = falling edge, 0 = rising edge mid bit
Bi-phase 1 creates an additional mid-bit change 0 creates an additional mid-bit change
Differential bi-phase 0 creates an additional mid-bit change 1 creates an additional mid-bit change
NRZ 1 = damping on, 0 = damping off 0 = damping on, 1 = damping off
Notes: 1. A common multiple of bit rate and FSK frequencies is recommended.
2. In PSK mode the selected data rate has to be an integer multiple of the PSK sub-carrier frequency.
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5.10.4 Fast DownlinkIn the optional fast downlink mode, the time between two gaps is reduced. In the fixed bit lengthprotocol mode, there are nominally 12 field clocks for a 0 and 28 field clocks for a 1. When thereis no gap for more than 32 field clocks after a previous gap, the ATA5577 in the Fixed Bit LengthProtocol mode will exit the downlink mode (refer to Table 5-10 on page 21).
For the timings in fast downlink mode of the long-leading-reference protocol refer to Table 5-11on page 22, for the leading-zero-reference protocol to Table 5-12 on page 23 and for the1-of-4-coding protocol to Table 5-12 on page 23.
5.10.5 Inverse Data OutputIn extended mode (X-mode), the ATA5577 supports an inverse data output option. If inversedata is enabled, the modulator as shown in Figure 5-3 works on inverted data (see Figure 5-8 onpage 14). This function is supported for all basic types of encoding.
Figure 5-3. Data Encoder for Inverse Data Output
5.11 Tag to Reader CommunicationDuring read operation (Uplink mode), the data stored within the EEPROM is cycled and the Coil1 and Coil 2 terminals are load modulated. This resistive load modulation can be detected at thereader device.
5.11.1 Regular-read ModeIn regular-read mode, data from the memory is transmitted serially, starting with block 1, bit 1, upto the last block (for example, 7), bit 32. The last block which will be read is defined by the modeparameter field MAXBLK in EEPROM block 0. When the data block addressed by MAXBLK hasbeen read, data transmission restarts with block 1, bit 1.
The user may limit the cyclic data stream in regular-read mode by setting the MAXBLK between0 and 7 (representing each of the 8 data blocks). If set to 7, blocks 1 through 7 can be read. If setto 1, only block 1 is transmitted continuously. If set to 0, the contents of the configuration block(normally not transmitted) can be read. In the case of MAXBLK = 0 or 1, regular-read mode cannot be distinguished from block-read mode.
FSK2
MUXData output
Data clock
ModulatorInverse data output
Intern outdata
Bi-phase
Manchester
FSK1
Direct/NRZ
PSK3
PSK2
PSK1
CLK
DSync
XOR
R
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Figure 5-4. Examples for Different MAXBLK Settings
Every time the ATA5577 enters regular- or block-read mode, the first bit transmitted is a logical0. The data stream starts with block 1, bit 1 and continues through MAXBLK, bit 32 and, if in reg-ular-read mode, cycles continuously.
Note: This behavior is different from the original e555x and helps to decode PSK-modulated data.
5.11.2 Block-read ModeWith the direct-access command, only the addressed block is read repetitively. This mode iscalled block-read mode. Direct access is entered by transmitting the page access opcode (“10”or “11”), a single 0 and the requested 3-bit block address when the tag is in normal mode.
In password mode (PWD bit set), the direct access to a single block needs the valid 32-bit pass-word to be transmitted after the page access opcode followed by a 0 and the 3-bit blockaddress. If the transmitted password does not match the contents of block 7, the ATA5577 tagreturns to regular-read mode.
Note: A direct access to block 0 of page 1 will read the configuration data of block 0, page 0.A direct access to block 4 to 7 of page 1 reads all data bits as zero.
5.11.3 Sequence Terminator (Basic Mode)The sequence terminator (ST) is a special damping pattern which is inserted in front of the firstblock and may be used to synchronize the reader. This sequence terminator is recommendedonly for FSK and Manchester coding. This Basic mode sequence terminator consists of four bitperiods. During the first and third bit period, the data value is 1. During the second and the fourthbit period, modulation is switched off (using Manchester encoding, switched on).
Bi-phase modulated data blocks need fixed leading and trailing bits in combination with thesequence terminator to be reliably identified.
The sequence terminator may be individually enabled by setting the mode bit 29 (ST = 1) inBasic mode (X-mode = 0).
In the regular-read mode, the sequence terminator is inserted at the start of each MAXBLK- lim-ited read data stream.
In block-read mode - after any block-write or direct access command - or if MAXBLK was set to1, the sequence terminator is inserted before the transmission of the selected block.
Especially this behavior is different to former ICs (e5551/T5551, T5554). For further details referto relevant application notes.
0
Loading block 0
Block 4 Block 5 Block 2Block 1Block 1
0
Loading block 0
Block 0 Block 0 Block 0Block 0Block 0
0
MAXBLK = 5
MAXBLK = 0
MAXBLK = 2
Loading block 0
Block 2 Block 1 Block 1Block 2Block 1
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ATMEL CONFID
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Figure 5-5. Read Data Stream with Sequence Terminator
Figure 5-6. Basic Mode Sequence Terminator Waveforms
5.11.4 Sequence Start Marker (X-mode)The ATA5577 sequence start marker is a special damping pattern in Extended mode, whichmay be used to synchronize the reader. The sequence start marker consists of two bits (“01” or“10”) which are inserted as header before the first block to be transmitted if in extended mode bit29 is set. At the start of a new block sequence, the value of the two bits is inverted.
Figure 5-7. ATA5577 Sequence Start Marker in Extended Mode
Block 2 MAXBLK Block 2Block 1Block 1
Sequence terminatorSequence terminator
Block 2 MAXBLK Block 2Block 1
Regular read mode
St = on
No terminator Block 1
Modulationoff (on)
Modulationoff (on)
Data 1Bit period Data 1
Waveforms per different modulation types
FSK
VCoilPPManchester
Sequence terminator is not suitable for Bi-phase or PSK modulation
Sequence Last bit
bit 1 or 0
First bit
Block 2 MAXBLK MAXBLKBlock 2Block 110 1001Block 1
Sequence start marker
Block read mode
Regular read mode
10 Block n10 Block n10 Block n 01 Block n 01 01Block n
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5.12 Reader to Tag CommunicationData is transmitted to the tag by interrupting the RF field with short field gaps (on-off keying) inaccordance with the T5557/ATA5567 write method (Downlink mode). The duration of these fieldgaps is, for example, 100 µs. The time between two gaps encodes the 0/1 information to betransmitted (pulse interval encoding). There are four different downlink protocols available,which are selectable via bit 21 and bit 22 in the option register block 3 page 1 (see Table 5-1 onpage 7). Choosing the default downlink protocol (fixed-bit-length protocol), the time between twogaps is nominally 24 field clocks for a 0 and 56 field clocks for a 1. When there is no gap formore than 64 field clocks after a previous gap, the ATA5577 exits the downlink mode. The tagstarts with the command execution if the correct number of bits were received. If a failure isdetected, the ATA5577 does not continue and enters regular-read mode.
Improved downlink performance could be achieved by choosing self-calibrating downlink proto-cols. The ATA5577 offers three different possibilities to get a better performance usingself-calibrating downlink protocols:
• Long leading reference:Fully forward and backward compatible with former tags and readers.
• Leading zero:A reader has to send a leading zero in front of the downlink bit stream. This leading zero serves as a reference for the following zero and one bits.
• 1 of 4 coding:Compact downlink protocol with optimized energy balance
5.12.1 Start GapThe initial gap is referred to as the start gap. This triggers the reader-to-tag communication. Inthe option register (block 3 page 1) several settings can be chosen to ease gap detection duringthis mode of operation, for example, the receive damping can be activated (see Table 5-1 onpage 7). The start gap may need to be longer than subsequent gaps — so-called write gaps —in order to be detected reliably.
A start gap will be accepted at any time after the mode register has been loaded (≥ 3 ms). A sin-gle gap will not change the previously selected page (by a previous opcode “10” or “11”).
Figure 5-8. Start of Reader-to-tag Communication
Write mode
Write damping settings
Read mode
Sgap Wgap
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ATMEL CONFID
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5.12.2 Downlink Data ProtocolsThe ATA5577 expects to receive a dual-bit opcode as a part of a reader command sequence.There are three valid opcodes:
• The opcode “10” precedes all downlink operations for page 0.
• The opcode “11” precedes all downlink operations for page 1. Performing a direct access command on block 0 always provides block 0 page 0 independently of the page selector (see Figure 4-2 on page 5).
• The RESET opcode “00” initiates an initialization cycle
The fourth opcode “01” precedes all test mode write operations. Any test mode access isignored after master key (bits 1 to 4) in block 0 has been set to “6”. Any further modifications ofthe master key are prohibited by setting the lock bit of block 0 or the OTP bit.
Downlink has to follow these rules:
• Standard write needs the opcode, the lock bit, 32 data bits and the 3-bit address (38 bits total)
• Protected write (PWD bit set) requires a valid 32-bit password between the opcode and the data and address bitsProtected write (PWD bit set) in conjunction with the leading-zero-reference protocol or with the 1-of-4-coding protocol requires two padding zero bits between the opcode and the password (see also Figure 5-17 on page 26). This ensures the uniqueness of the direct access with password and the standard write command (see also Table 6-1 on page 27).
• For the AOR wake-up command an opcode and a valid password are necessary to select and activate a specific tag
Note: The data bits are read in the same order as written.
If the transmitted command sequence is invalid, the ATA5577 enters regular-read mode with thepreviously selected page (by previous opcode “10” or “11”).
Table 5-9. Gap Scheme
Parameters Remark Symbol Min. Max. Unit
Start gap Sgap 8 50 TC
Write gap Normal downlink mode Wgap 8 20 TC
Note: All absolute times assume TC = 1 / fC = 8 µs (fC = 125 kHz)
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Figure 5-9. Complete Writing Sequence with Fixed-bit-length Protocol
Figure 5-10. ATA5577 Command Formats Fixed-bit-length Protocol and Long-leading-reference Protocol
Write mode Read modeRead mode
ProgrammingBlock addressBlock data
Lock bitStart gapConfiguration
loading
POR
Dampin duringinitialization Opcode
Password 32 01
OP
Password 321
1p*) 0 Addr 02
**) R = Reference pulse if necessary
*) p = page selector00
1p*)
1p*) L Data
Addr 02
Addr 02321
1p*)
1p*)
Ref
R**)
R**)
R**)
R**)
R**)
R**)
R**)AOR (wake-up command)
Reset command
Page 0/1 regular read
Standard write
Direct access (PWD = 0)
Direct access (PWD = 1)
Protected write 1 Data AddrLPassword 32 2132 0
1p*)
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Figure 5-11. ATA5577 Command Formats Leading-zero-reference Protocol and 1-of-4-coding Protocol
5.12.3 Fixed-bit-length Protocol In the fixed-bit-length protocol, the time between two gaps is nominally 24 field clocks for a 0 and56 field clocks for a 1. When there is no gap for more than 64 field clocks after a previous gap,the ATA5577 exits the downlink mode. This protocol is compatible to the T5557/ATA5567transponder.
Figure 5-12. Fixed Bit Length Protocol
Password 32 0100
00
OP
Password 321
1p*) 0 Addr 02
**) R = Reference pulse
*) p = page selector00
1p*)
1p*) L Data
Addr 02
Addr 02321
1p*)
1p*)
Ref
R**)
R**)
R**)
R**)
R**)
R**)
R**)AOR (wake-up command)
Reset command
Page 0/1 regular read
Standard write
Direct access (PWD = 0)
Direct access (PWD = 1)
Protected write 100 Data AddrLPassword 32 2132 0
1p*)
Table 5-10. Downlink Data Coding Scheme with Fixed-bit-length Protocol
Parameter Remark Symbol
Normal Downlink Fast Downlink
UnitMin. Typ. Max. Min. Typ. Max.
Start gap Sgap 8 15 50 8 15 50 Tc
Write gap Wgap 8 10 20 8 10 20 Tc
Write data coding (gap separation)
0 data d0 16 24 32 8 12 16 Tc
1 data d1 48 56 64 24 28 32 Tc
Note: All absolute times assume TC = 1 / fC = 8 µs (fC = 125 kHz)
1 0
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5.12.4 Long-leading-reference ProtocolTo achieve better downlink performance, an enhanced ATA5577 reader places a referencepulse in front of the opcode. This reference pulse is used as a timing reference for all followingdata, thus providing an auto-adjustment for varying environmental conditions. The long-lead-ing-reference protocol allows full compatibility and coexistence of both T5557/ATA5567 andATA5577 devices with both T5557/ATA5567 compatible readers and advanced ATA5577 read-ers. However, only the ATA5577 devices can profit from the self-calibration and the resultantincrease in write distance (see Table 5-1 on page 7 for option register settings).
In this mode, the reference pulse in front of the command is monitored. Depending on its length,the remainder of the command is either evaluated using the fixed-bit-length protocol or this pulseis used as a measurement reference to evaluate the following command bits. Otherwise the fol-lowing bits are considered as an invalid command.
a) For a reference-based command, the reference pulse (dRef) will have a length of 16 to 32 + 136 = 152 to 168 field clocks (zero bit + timing bias = reference pulse). Hence theexpected length will lie between 152 and 168 field clocks. The equivalent expected zero bitlength is then extracted and used as a reference for all following bits. The long-leading-referencepulse in this case is used as a timing reference only and does not contribute to the commanddata itself (see Figure 5-13, part a on page 23).
b) should the first bit lie within the fixed bit length frame (for example in normal mode: 0: 16 to 32clocks; 1: 48 to 64 clocks) the device will then automatically switch to the fixed-bit-length proto-col (see Section 5.12.3 “Fixed-bit-length Protocol” on page 21) and this first pulse will beevaluated as the first command bit. This allows compatibility with long-leading-reference pro-grammed ATA5577 devices interacting with T5557/ATA5567 readers, which do not send anyreference pulses (see Figure 5-13, part b on page 23).
c) If a T5557/ATA5567 device interacts with an enhanced ATA5577 reader, the reference pulse(152 to 168 field clocks) is ignored by the T5557/ATA5567 and the following data bits will evalu-ated correctly. Therefore a T5557/ATA5567 device is compatible with an enhanced ATA5577reader (see Figure 5-13, part b on page 23).
d) Should the first bit correspond to neither (a) nor (b) then it will be rejected as an invalidcommand.
Table 5-11. Downlink Data Coding Scheme with Long Leading Reference
Parameter Remark Symbol
Normal Downlink Fast Downlink
UnitMin. Typ. Max. Min. Typ. Max.
Start gap Sgap 8 15 50 8 15 50 Tc
Write gap Wgap 8 10 20 8 10 20 Tc
Write data coding (gap separation)
Reference Pulse dref
152 160 168 140 144 148Tc
136 clocks + 0 data bit 132 clocks + 0 data bit
0 data d0 dref – 143 dref – 136 dref – 128 dref – 135 dref – 132 dref – 124 Tc
1 data d1 dref – 111 dref – 104 dref – 96 dref – 119 dref – 116 dref – 112 Tc
Note: All absolute times assume TC = 1 / fC = 8 µs (fC = 125 kHz)
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Figure 5-13. Long-leading-reference Protocol
5.12.5 Leading-zero-reference ProtocolIf the device is programmed in this mode it will always expect a reference pulse before the com-mand data itself. This pulse length should correspond exactly to the length of the zero bits in thefollowing command. All further lengths of the zero bits and one bits of the command are derivedfrom the reference pulse. Therefore, downlink performance is optimal in different environmentalconditions.
Figure 5-14. Leading Zero Reference Protocol
1Reference pulse 0
a)
1 0
b)
1Reference pulse 0
c)
Table 5-12. Downlink Data Coding Scheme with Leading-zero Reference
Parameter Remark Symbol
Normal Downlink Fast Downlink
UnitMin. Typ. Max. Min. Typ. Max.
Start gap Sgap 8 15 50 8 15 50 Tc
Write gap Wgap 8 10 20 8 10 20 Tc
Write data coding (gap separation)
Reference Pulse dref 12 – 72 8 – 68 Tc
0 data d0 dref – 7 dref dref + 8 dref – 3 dref dref + 4 Tc
1 data d1 dref + 9 dref + 16 dref + 24 dref + 5 dref + 8 dref + 12 Tc
Note: All absolute times assume TC = 1 / fC = 8 µs (fC = 125 kHz)
1 0(0)
Reference pulse
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5.12.6 1-of-4-coding ProtocolThis protocol codes the data in bit pairs so that the length of each packet can have one of fourdiscrete lengths. This protocol is extremely compact and exhibits the least number of field gapswhich in turn improves the device’s ability to extract power from the field. Additionally a leadingreference pulse “00” is placed in front of the downlink command. This serves as a referencepulse for all following data bits, thus providing an auto-adjustment for varying environmentalconditions.
Figure 5-15. 1 of 4 Coding Protocol
Table 5-13. Downlink Data Coding Scheme with 1-of-4 Coding
Parameter Remark Symbol
Normal Downlink Fast Downlink
UnitMin. Typ. Max. Min. Typ. Max.
Start gap Sgap 8 15 50 8 15 50 Tc
Write gap Wgap 8 10 20 8 10 20 Tc
Write data coding (gap separation)
Reference pulse “00” dref 12 – 72 8 – 68 Tc
“00” data d00 dref – 7 dref dref + 8 dref – 3 dref dref + 4 Tc
“01” data d01 dref + 9 dref + 16 dref + 24 dref + 5 dref + 8 dref + 12 Tc
“10” data d10 dref + 25 dref + 32 dref + 40 dref + 13 dref + 16 dref + 20 Tc
“11” data d11 dref + 41 dref + 48 dref + 56 dref + 21 dref + 24 dref + 28 Tc
Note: All absolute times assume TC = 1 / fC = 8 µs (fC = 125 kHz)
Reference pulse
(00) 00
Reference pulse
(00) 10
01 10 11
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Figure 5-16. Standard Write Sequence Example
1 00 1 11 01 00
00 0 1 1 010 00 11
0 01 0 1 10 10 01
1 00 1 11 01 00
Opcode Blockdata: "100 ... 1" Blockaddr.: "011" Programming Read modeRead mode
c) Leading Zero Reference Protocol
OpcodeBlockdata:"100 ... 1"
Blockaddr.:"011" Programming Read modeRead mode
d) 1 of 4 Coding Protocol
Opcode Blockdata: "100 ... 1" Blockaddr.: "011" Programming Read modeRead mode
OpcodeReference Pulse
Reference Pulse
Start gap Lock bit
Reference Pulse
Blockdata: "100 ... 1" Blockaddr.: "011" Programming Read modeRead mode
Start gap Lock bit
Start gap Lock bit
Start gap Lock bit
a) Fixed Bit Length Protocol
b) Long Leading Reference Protocol
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Figure 5-17. Protected Write Sequence Example
5.13 ProgrammingWhen all necessary information has been received by the ATA5577, programming may proceed.There is a clock delay between the end of the writing sequence and the start of programming.
Typical programming time is 5.6 ms. This cycle includes a data verification read to grant secureand correct programming. After programming is successfully executed, the ATA5577 entersblock-read mode, transmitting the block just programmed (see Figure 5-18 on page 27).
Note: This timing and behavior is different from the e555x-family predecessors. For further details refer to relevant Atmel application notes.
If the command sequence is validated and the addressed block is not write protected, the newdata will be programmed into the EEPROM memory. The new state of the block write protectionbit (lock bit) will be programmed at the same time accordingly.
Each programming cycle consists of four consecutive steps: erase block, erase verification(data = 0), programming, and write verification (corresponding data bits = 1).
1 1 0 00 10 110 1 110
1 1 0 00 10 110
0
00 000 1 1 001 11111000
1 0 0 1 00 1 01 00 101
1 110
Start gap Lock bit
Start gap Lock bit
Lock bit
Opcode PWD: "1101 ... " Blockdata: "100 ... 1" Blockaddr.: "011" Programming Read modeRead mode
a) Fixed Bit Length Protocol
Padding zerosStart gap
Opcode PWD: "1101 ... " Blockdata: "100 ... 1" Blockaddr.: "011" Programming Read modeRead mode
c) Leading Zero Reference Protocol
Opcode PWD: "1101 ... "Blockdata:"100 ... 1"
Blockaddr.:"011" Programming Read modeRead mode
d) 1 of 4 Coding Protocol
Reference Pulse
Reference Pulse
Lock bitPadding zerosStart gap
Reference Pulse
Opcode PWD: "1101 ... " Blockdata: "100 ... 1" Blockaddr.: "011" Programming Read modeRead mode
b) Long Leading Reference Protocol
1 1
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ATMEL CONFID
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Figure 5-18. Coil Voltage after Programming a Memory Block
Notes: 1. Programming of page 1 with following single gap will lead to a page 1 read. To enter regu-lar-read mode, a POR or Reset command has to be performed.
6. Error HandlingSeveral error conditions can be detected to ensure that only valid bits are programmed into theEEPROM. There are two error types, which lead to two different actions.
6.1 Errors During Command SequenceThe following detectable errors could occur sending a command sequence to the ATA5577:
• Wrong number of field clocks between two gaps (that is, not a valid 1 or 0 pulse stream)
• Password mode is activated and the password does not match the contents of block 7
• The number of bits received in the command sequence is incorrect
Valid bit counts accepted by the ATA5577 are:
If any of these erroneous conditions (except AOR mode) are detected, the ATA5577 enters reg-ular-read mode, starting with block 1 of the page defined in the command sequence. Anerroneous AOR wake-up command will stop modulation (modulation defeat).
Read programmedmemory block
POR/ Reset
or Read block 1 to MAXBLK5.6 ms
Singlegap
(Regular-read mode)(Block-read mode)Programming anddata verification
Write data to tag
VCoil 1 - Coil 2
Table 6-1. Bit Counts of Command Sequences
Command Protect
Fixed-bit-length
Protocol
Long-leading-reference Protocol
Leading-zero- reference Protocol
1-of-4- coding
Protocol
Standard write (PWD = 0) 38 bits 38 bits 38 bits 38 bits
Direct access (PWD = 0) 6 bits 6 bits 6 bits 6 bits
Password write (PWD = 1) 70 bits 70 bits 72 bits 72 bits
Direct access with PWD (PWD = 1) 38 bits 38 bits 40 bits 40 bits
AOR wake-up (PWD = 1) 34 bits 34 bits 36 bits 36 bits
Reset command 2 bits 2 bits 2 bits 2 bits
Page 0/1 regular read 2 bits 2 bits 2 bits 2 bits
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6.2 Errors Before/During Programming the EEPROMIf the command sequence was received successfully, the following error could still preventprogramming:
• The lock bit of the addressed block is set already
• In case of a locked block, programming mode will not be entered. The ATA5577 reverts to block-read mode continuously transmitting the currently addressed block.
• If a data verification error is detected after an executed data block programming, the tag will stop modulation (modulation defeat) until a new command is transmitted.
Figure 6-1. ATA5577 Functional Diagram
addr = current
Block-read mode
addr = 1 to MAXBLK
Program and verify
Write
Password check
Lock bit check
Number of bits
OP(10..)
Command decodeOP(11..)
Startgap
WriteOP(1p) 1)
OP(1p) 1)
1) p = page selector
Direct accessOP(1p) 1)Modulation
defeat
Resetto page 0
Test modeif master key < > 6
AOR = 1
Page 0
Single gap
OP(01)OP(00)
Page 0Page 1
Page 0 or 1
fail data = old
fail data = old
fail data = old
Gap
Gap Command mode
AOR = 0
Set-up modes
Power-on reset
Regular-read mode
AOR mode
okData verification failed data = new
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Figure 6-2. Example with Manchester Coding with Data Rate RF/16
Dat
a ra
te =
16
fiel
d cl
ocks
(F
C)
11
01
00
8 F
C
89
116
91
81
816
916
1616
916
81
98
21
82
1
8 F
C
Man
ches
ter
code
d
Inve
rted
mod
ulat
orsi
gnal
RF
fiel
d
Dat
a st
ream
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Figure 6-3. Example of Bi-phase Coding with Data Rate RF/16
916
98
1616
916
1
81
82
18
21
816
91
816
91
Bi-p
hase
cod
ed
Inve
rted
mod
ulat
orsi
gnal
RF
fiel
d
Dat
a st
ream
Dat
a ra
te =
16
fiel
d cl
ocks
(F
C)
11
10
00
8 F
C8
FC
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Figure 6-4. Example: FSK1a Coding with Data Rate RF/40, Sub-carrier f0 = RF/8, f1 = RF/5
51
51
51
81
81
81
Inve
rted
mod
ulat
orsi
gnal
RF
fiel
d
f 0 =
RF
/8
f 1 =
RF
/5
Dat
a st
ream
Dat
a ra
te =
40
fiel
d cl
ocks
(F
C)
11
01
00
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Figure 6-5. Example of PSK1 Coding with Data Rate RF/16
169
88
21
116
81
168
116
81
168
1
Sub
carr
ier
RF
/2
Inve
rted
mod
ulat
orsi
gnal
RF
fiel
d
Dat
a st
ream
Dat
a ra
te =
16
fiel
d cl
ocks
(F
C)
10
01
10
8 F
C8
FC
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Figure 6-6. Example of PSK2 Coding with Data Rate RF/16
168
116
81
168
116
81
169
88
21
1S
ubca
rrie
r R
F/2
Inve
rted
mod
ulat
or s
igna
l
RF
fiel
d
Dat
a st
ream
Dat
a ra
te =
16
fiel
d cl
ocks
(F
C)
10
00
11
8 F
C8
FC
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Figure 6-7. Example of PSK3 Coding with Data Rate RF/16
168
18
161
816
81
168
116
98
21
1S
ubca
rrie
r R
F/2
Inve
rted
mod
ulat
or s
igna
l
RF
fiel
d
Dat
a st
ream
Dat
a ra
te =
16
fiel
d cl
ocks
(F
C)
10
10
01
8 F
C8
FC
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7. Animal IDIn ISO11784/11785, the code structure of a 128-bit FDX-B telegram is defined. Following is anexample of how to program the ATA5577 for ISO 11785 FDX-B.
Figure 7-1. Structure of the ISO 11785 FDX-B Telegram
Notes: 1. Except for the header, every 8 bits are followed by one control bit (1), to prevent the header from recurring.
2. All data is transmitted LSB first.
3. Country codes are defined in ISO 3166
4. The bits reserved for future use (RFU) are all set to 0.
5. If the data block flag is not set, the trailer bits are all set to 0.
6. CRC is performed on the 64-bit identification code without the control bits. The generator poly-nomial is P(x) = x16 + x12 + x5 + 1. Reverse CRC-CCITT (0x 8 408) is used. Data stream is LSB first.
Programming of the ATA5577 for animal ID:
• Encoding of the data is differential bi-phase RF/32
• 128 bits have to be transmitted in regular-read mode (Maxblock = 4)
11
Header
11-bit fixed00000000001
24-bit trailer all zeros+ 3 bits
16-bit CRC+ 2 bits
TrailerCRCIdentification Code
64-bit Identification Code+ 8 bits
Bit No.
Bits
128102 ...10184 ...
1220 ...Bit No. 83 ...
832012 ... ...111 ...
2 x (8+1) 3 x (8+1)8 x (8+1)
Control bit '1'LSB LSBMSB
LSBMSB
MSB
Con
trol
bit
'1'
Dat
a B
lock
Fla
g
Ani
mal
Fla
gC
ontr
ol b
it '1
'
Con
trol
bit
'1'
Con
trol
bit
'1'
Con
trol
bit
'1'
Con
trol
bit
'1'
Con
trol
bit
'1'
Cou
ntry
Cod
e2
bits
Con
trol
bit
'1'
RFU 7 bitsUniqueNumber
6 bits
UniqueNumber 8 bits
UniqueNumber 8 bits
UniqueNumber 8 bits
UniqueNumber 8 bits
Country Code8 bitsRFU 7 bits
RFU 14 bits Country Code 10 bits Unique Number 38 bits
Table 7-1. Example Data for Animal ID
Code Dec. Value Hex. Value Comment
Animal flag 1 1 Use for animal ID
RFU 0 0 Reserved for future use
Data block flag 0 0 No data in trailer
Country code 999 3E7 Country code for demo tags
Unique number 78187493530 123456789A Any demo number
CRC 36255 8D9F CRC for the identification code
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Table 7-2. Programming the ATA5577 with Example Data
Block Address Value Comment
Option register Block 3, page 1 0x 6DD0 0000(1) Soft modulation, two pulses recommended
Configuration register Block 0, page 0 0x 603F 8080 RF/32, differential bi-phase, Maxblock = 4
User data block 1 Block 1, page 0 0x 002B 31EB Header, unique number
User data block 2 Block 2, page 0 0x 54B2 979F Unique number (cont.), country code
User data block 3 Block 3, page 0 0x 8040 7F3B Data block flag, RFU, animal flag, CRC
User data block 4 Block 4, page 0 0x 1804 0201 CRC (cont.), trailer bits
Note: 1. Depending on application, settings may vary
8. Absolute Maximum RatingsStresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.
Parameters Symbol Value Unit
Maximum DC current into Coil1/Coil2 Icoil 20 mA
Maximum AC current into Coil1/Coil2, f = 125 kHz Icoil p 20 mA
Power dissipation (die) (free-air condition, time of application: 1s)
Ptot 100 mW
Electrostatic discharge maximum to ANSI/ESD-STM5.1-2001 standard (HBM)
Vmax 3000 V
Operating ambient temperature range Tamb –40 to +85 °C
Storage temperature range (data retention reduced)
Tstg –40 to +150 °C
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9. Electrical CharacteristicsTamb = +25°C; fcoil = 125 kHz; unless otherwise specified
No. Parameters Test Conditions Symbol Min. Typ. Max. Unit Type*
1 RF frequency range fRF 100 125 150 kHz
2.1
Supply current (without current consumed by the external LC tank circuit)
Tamb = 25°C(1)
IDD
1.5 3 µA T
2.2Read - full temperature range
2 5 µA Q
2.3Programming - full temperature range
25 µA Q
3.1
Coil voltage (AC supply)
POR threshold (50-mV hysteresis)
Vcoil pp
3.6 V Q
3.2Read mode and write command(2) 6 Vclamp V Q
3.3 Program EEPROM(2) 8 Vclamp V Q
4 Start-up time Vcoil pp = 6V tstartup 2.5 ms Q
5.1
Clamp voltage (depends on settings in option register)
3-mA current into Coil1/Coil2
Vpp clamp lo 11 V Q
5.2 Vpp clamp med 13 V Q
5.3 Vpp clamp hi 14 17 21 V T
5.420-mA current into Coil1/Coil2
Vpp clamp med 13 15 18 V T
6.1
Modulation parameters (depends on settings in option register)
3-mA current into Coil1/Coil2 and modulation ON
Vpp mod lo 2 3 4 V T
6.2 Vpp mod med 5 V Q
6.3 Vpp mod hi 7 V Q
6.420 mA current into Coil1/Coil2 and modulation ON
Vpp mod med 6 7.5 9 V T
6.5 Thermal stability Vmod lo/Tamb –1 mV/°C Q
7.1 Clock detection level (depends on settings in option register)
Vcoil pp = 8V
Vclkdet lo 250 mV Q
7.2 Vclkdet med 400 550 730 mV T
7.3 Vclkdet hi 800 mV Q
7.4 Gap detection level (depends on settings in option register)
Vcoil pp = 8 V
Vgapdet lo 250 mV Q
7.5 Vgapdet med 400 550 730 mV T
7.6 Vgapdet hi 850 mV Q
8 Programming time
From last command gap to re-enter read mode (64 + 648 internal clocks)
Tprog 5 5.7 6 ms T
9 Endurance Erase all/Write all(3) ncycle 100000 Cycles Q
*) Type means: T: directly or indirectly tested during production; Q: guaranteed based on initial product qualification data
Notes: 1. IDD measurement set-up: EEPROM programmed to 00 ... 000 (erase all); chip in modulation defeat.
2. Current into Coil1/Coil2 is limited to 10 mA.
3. Since EEPROM performance is influenced by assembly processes, Atmel can not confirm the parameters for -DDW (tested die on unsawn wafer) delivery.
4. See Section 10. “Ordering Information” on page 39.
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10.1
Data retention
Top = 55°C(3) tretention 10 20 50 Years Q
10.2 Top = 150°C(3) tretention 96 hrs T
10.3 Top = 250°C(3) tretention 24 hrs Q
11.1
Resonance capacitorMask option(4)
Vcoil pp = 1VCr
320 330 340
pF
T
11.2 242 250 258
11.3 130
11.4 75
11.5 10 Q
12.1Micromodule capacitor parameters
Capacitance tolerance Tamb
Cr 320 330 340 pF T
9. Electrical Characteristics (Continued)Tamb = +25°C; fcoil = 125 kHz; unless otherwise specified
No. Parameters Test Conditions Symbol Min. Typ. Max. Unit Type*
*) Type means: T: directly or indirectly tested during production; Q: guaranteed based on initial product qualification data
Notes: 1. IDD measurement set-up: EEPROM programmed to 00 ... 000 (erase all); chip in modulation defeat.
2. Current into Coil1/Coil2 is limited to 10 mA.
3. Since EEPROM performance is influenced by assembly processes, Atmel can not confirm the parameters for -DDW (tested die on unsawn wafer) delivery.
4. See Section 10. “Ordering Information” on page 39.
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10. Ordering Information
Note: A special version with damping during initialization could be generated on request (see also Section 5.5 “Initialization and Init-Delay” on page 10)
ATA5577M t ccc -xxx Package Drawing
DDB6” sawn wafer on foil with ring, thickness 150 µm (approx. 6 mil)
Figure 11-3 on page 43
DBB6” sawn wafer on foil with ring and NiAu bumps 25 µm, thickness 150 µm (approx. 6 mil)
Figure 11-4 on page 44
DDW 6” wafer, thickness 250 µm (approx. 10 mil) on request
DDT Die in waffle pack, thickness 150 µm (approx. 6 mil) Figure 11-8 on page 48
PAE NOA3 micromodule (lead-free, planned)Figure 11-6 on page 46/Figure 11-7 on page 47
On-chip Capacity Value in pF
000 (planned)
075 (planned)
250
330
Type
1 Standard pads
ATA5577M t ccc -xxx Package Drawing
DBB6” sawn wafer on foil with ring and gold bumps 25 µm, thickness 150 µm (approx. 6 mil)
Figure 11-5 on page 45
DDTDie in waffle pack, thickness 150 µm (approx. 6 mil, on request)
Figure 11-9 on page 49
DBNDie on sticky tape with goldbumps 25 µm, thickness 280 µm (approx. 11 mil)
Sticky Tape: 3M 7419
On-chip Capacity Value in pF
000 (on request)
075 (planned)
250
330
Type
2 Mega pads
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10.1 Available Order CodesATA5577M1250-DDTATA5577M1250-DDBATA5577M1330-DDTATA5577M1330-DDBATA5577M1330-DBBATA5577M1330-PAEATA5577M2250-DBBATA5577M2330-DBBATA5577M2330-DBN
New order codes will be created by customer request if order quantities are over 250k pieces.
10.2 Configuration on Delivery
Table 10-1. Configuration on Delivery
Block Address Value Comment
AFE option set-up Block 3, page 1 0x 0000 0000 All option take on the default state
Configregister Block 0, page 0 0x 0008 8040 RF/32, Manchester, Maxblock =2
User data block 1 Block 1, page 0 0x 0000 0000 All “0”
User data block 2 Block 2, page 0 0x 0000 0000 All “0”
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11. Package Information
Figure 11-1. Pad Layout, (Type 1, Standard Pads)
1150
1000
95
117
100 181
70
8080
100
125
347
Dimensions in µm
ATA5577
C1 C2
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Figure 11-2. Pad Layout (Type 2, Mega Pads)
1000
1355
8080
C1 C2
400
200
70
125
238377
95
124
40
ATA5577
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Figure 11-3. Sawn Wafer on Foil with Ring (Type 1, Standard Pads)
0.15±0.012
Issue: 2; 11.01.08
Drawing-No.: 9.920-6676.01-4
Wafer ATA5577M1
6" Wafer frame, plasticthickness 2.5mm
UV Tape NITTO DU-200
Label:
Qty:Wafer no:PLot no:Prod: ATA5577M159.5 63.6
4 B
B
212
∅ 194.5
∅ 150
∅ 227.7
A
A
∅3
212
87.5
86.5
20:1
Die Dimensions
Dimensions in mm
specificationsaccording to DINtechnical drawings
Orientation on frame
00
0.09
5
0.90
5
0.04
0.18
1
C1 C2
(0.0
8)
0.1
0.12
5
1.151.11
0.1170.040
0.1
0.07(0.08)
0.803
0.81
90.
961
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Figure 11-4. Sawn Wafer on Foil with Ring (Type 1, Standard Pads and NiAu Bumps)
0.025±0.005
(NiAu bump)
0.15±0.012
Issue: 1; 11.01.08
Drawing-No.: 9.920-6676.02-4
Wafer ATA5577M1
6" Wafer frame, plasticthickness 2.5mm
UV Tape NITTO DU-200
Label:
Qty:Wafer no:PLot no:Prod: ATA5577M159.5 63.6
4 B
B
212
∅ 194.5
∅ 150
∅ 227.7
A
A
∅3
212
87.5
86.5
20:1
Die Dimensions
Dimensions in mm
specificationsaccording to DINtechnical drawings
Orientation on frame
C1 C2
00.
095
0.90
5
(0.0
8)
0.1
0.12
5
0.07(0.08)0 0.
040.
181
1.151.11
0.1170.040
0.1
0.803
0.81
90.
961
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ATMEL CONFID
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Figure 11-5. Sawn Wafer on Foil with Ring (Type 2, Mega Pads and Au Bumps)
20:1
Die Dimensions
0 0.04
0.23
8
C1 C2
(0.0
8)
0.4
00.04
0.2(Au bump)
(BCB coating)(0.08)
0.377
1.3151.355
Issue: 1; 10.01.08
Drawing-No.: 9.920-6679.01-4
0.15±0.012
0.025±0.005
0.006±0.001
Wafer ATA5577M2
6" Wafer frame, plasticthickness 2.5mm
UV Tape NITTO DU-200
Label:
Qty:Wafer no:PLot no:Prod: ATA5577M2
∅ 227.7
212
∅ 194.5
A
A
∅3∅ 150
59.5 63.6
212
87.5
86.5
4 B
Dimensions in mm
specificationsaccording to DINtechnical drawings
BOrientation on frame
0.76
20.
961
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Figure 11-6. NOA3 Micromodule
Not
e 2
Not
e 4
8-0.
02
8.1±
0.03
5.1±
0.05
1.42
±0.
05
specificationsaccording to DINtechnical drawings
Dimensions in mm
Note:1. Reject hole by testing device2. Punching cutline recommendation for singulation
3. Total package thickness exclusive punching burr
4. Module dimension after electrical disconnection
Issue: 1; 28.04.06
Subcontractor: NedCard
Drawing refers to following types: Micromodule NOA-3
Drawing-No.: 6.549-5035.01-4
9.5±0.03
4.8±0.05
5.15±0.03
1.42±0.05
4.75+0.02
0.05
B
0.03
4.625
1.58502.515
6.265
12.165
15.915
31.83
21.815
Note 1
Note 2
5.06±0.03
R1.5±0.03
R1.1±0.03 (4x)
R0.2 max.
Note 4
0.09-0.01
0.38-0.035
Note 3
A
X
X5:1
2.375
2.375
B
25.565
BA
0.03 B
0.05 A
∅ 2±0.05
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ATMEL CONFID
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Figure 11-7. Shipping Reel for NOA3 Micromodule
Ø 329.6
120̊
(3x)
16.7
Ø171
Ø175
R1.14
Ø132.3
41.4 tomax 43.0
Ø 2
98.5
2.2
2
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Figure 11-8. Die in Waffle Pack (Type 1)
TITLE DRAWING NO. REV. Package Drawing Contact: [email protected] 9.920-6686.01-4
Tray: H20-045057-17Material: PS, black,
conductive
COMMONDIMENSIONS
(Unit of Measure = mm)
1Chip DimensionsATA5577M1
03/05/08
Dimensions in mm
specificationsaccording to DINtechnical drawings
2.21 B0
A0
1.92
K0
5:1
1.15
0.1170.1
0.125
0.347
A0
1.14
K0
0.43
B0
1.44
Chip orientation
Chip identification ATA5577M1
(0.08)
0.07
0.09
5
0.1
1
C2
C1
C2
C1
0.18
1(0
.08)
20:1
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ATMEL CONFID
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Figure 11-9. Die in Waffle Pack (Type 2)
TITLE DRAWING NO. REV. Package Drawing Contact: [email protected] 9.920-6687.01-4
Tray: H20-062052-17Material: PS, black,
conductive
COMMONDIMENSIONS
(Unit of Measure = mm)
1Chip DimensionsATA5577M2
03/05/08
Dimensions in mm
specificationsaccording to DINtechnical drawings
2.25
1.355
A0
1.32
K0
0.43
B0
1.57
(0.08)
0.177
0.4
B0
Chip orientation
Chip identification ATA5577M2
A0
2.02
(0.0
8)
C1
C2
0.2
1
0.32
4
45.6
50.8
K0
5:1
20:1
0.04×45˚
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12. Revision History
Please note that the following page numbers referred to in this section refer to the specific revision mentioned, not to this document.
Revision No. History
4867CX-RFID-12/08
• Section 9 “Electrical Characteristics” on pages 37 to 38 changed
• Section 10 “Ordering Information” on page 39 changed• Section 10.1 “Available Order Codes” on page 40 changed
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4967CX–RFID–12/08
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Atmel Corporation2325 Orchard ParkwaySan Jose, CA 95131USATel: 1(408) 441-0311Fax: 1(408) 487-2600
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